RU98118377A - ELECTRIC HEATING SYSTEM - Google Patents

Claims (26)

1. The method of heating the carrier using several different electric heaters surrounded by thermal insulation, and the heaters are placed between the carrier and thermal insulation, and the carrier has at least two different zones, each of which is heated by one or more heaters, heating only this zone characterized in that each of these heaters is turned on and off for successive and alternating periods of heating and cooling, with durations that maintain the temperature tours of all parts of the carrier are not lower than the selected minimum temperature and sequentially calculated at successive discrete time instants, and these durations are determined by one microprocessor independently for each zone as a function of the ambient temperature near the carrier at the time of calculation or at one or more earlier times. 2. The method according to p. 1, characterized in that it is performed by a microprocessor having a memory in which, for each section or each group of sections having similar thermal requirements, the thermal characteristics corresponding to the most vulnerable most rapidly cooled part of the section or group of sections are recorded , thermal insulation surrounding the aforementioned part, and a heater adjacent to the aforementioned part, and the duration of each heating period and the immediately following cooling period elyayut simultaneously as a function of the time periods needed, at a given ambient temperature at the moment, for heating the aforementioned most vulnerable part from the lower limit temperature T _L to a higher temperature and then cooling again to a temperature T _L at the end of the cooling period. 3. The method according to p. 1 or 2, characterized in that it is carried out for a carrier with a plurality of pipes connected to each other, and the heater is elongated, while the duration of the heating and cooling periods are functions for time periods required at a given ambient temperature , to heat the aforementioned most vulnerable part from the lower limit temperature) T _L to the upper limit temperature T _U , where the value of T _U -T _L is in the range of 0.5 - 8.3 ^o C (1 - 15 ^o F), and the subsequent cooling again to temperature) T _L.  4. The method according to PP. 1-3, characterized in that it is carried out for a carrier having at least 5 zones, each of which is heated by at least one self-regulating heater having a length of at least 4.5 meters (15 feet).  5. A method for heating a fluid transport system containing a set of pipes surrounded by thermal insulation and having several zones with different thermal requirements, and at least one elongated electric heater installed between the pipes of this zone and the thermal insulation surrounding them in each zone characterized in that said heater in each zone is turned on and off for successive periods of heating and cooling, maintaining the temperature of all pipes of this zone above the minimum temperature and the method also includes separately for each of the zones (1) determining the heating duration for each successive heating period as a function of the ambient temperature at one or more separate time points before the end of the heating period, (2) determining the cooling duration for each successive period cooling as a function of ambient temperature at one or more separate time points before the end of the cooling period, (3) turning on the heater for successive heating periods , the duration of which is determined in step (2), and (4) the heater is turned off for successive cooling periods, the duration of which is determined in step (3).  6. The method according to p. 5, characterized in that to determine the duration of heating and cooling for each of the heaters using one microprocessor.  7. The method according to p. 5 or 6, characterized in that the ambient temperature is measured in one place, and the duration of heating and cooling for all heaters is determined as a function of the ambient temperature measured by the sensor in this place.  8. The method according to PP. 5 to 7, characterized in that the duration of heating and cooling for each heater is determined at successive discrete time points, divided into time intervals of 5 to 15 minutes 9. The method according to PP. 5 to 8, characterized in that the heating time is a function of the time required, at an ambient temperature at a particular point in time, for heating the reference carrier with a reference heater from the lower limit temperature T _L to the upper limit temperature T _U , where T _U -T _L is in the range of 0.5 - 8.3 ^o C (1 - 15 ^o F), and the duration of cooling is a function of the time required at ambient temperature at a separate discrete time point for cooling the reference carrier T _U -T _L , moreover, the reference n the carrier is surrounded by a reference insulation, and a reference heater is placed between the reference carrier and the reference insulation.  10. The method according to p. 9, characterized in that the reference medium corresponds to the part of the zone that is most rapidly cooled, the reference heater is a heater heating this part of the zone, and the reference insulation is the insulation surrounding this part. 11. The method according to p. 9 or 10, characterized in that the duration of each heating period and the duration immediately preceding it or immediately following the cooling period are functions of the ambient temperature measured at a certain point in time, and the duration of each heating period in hours is determined the following expression:
(I) -RC ln [1 - (T _U - T _L ) / (T _A + RQ - T _L )]
and the duration of each cooling period in hours is determined by the following expression:
(II) -RC ln [1 - (T _U - T _L ) / (T _U - T _A )]
where R is the effective thermal resistance of the reference thermal insulation surrounding the reference carrier, expressed in units of hours ° F / BTU (BTU - British thermal unit [BTU] - 0.252 kg / kcal);
C is the heat capacity of the reference medium, expressed in units of BTU / ^o F;
T _U is the upper temperature limit, expressed in ° F;
T _L is the lower temperature limit, expressed in ^o F;
T _A is the ambient temperature at a certain point in time, expressed in ^o F; T _{A is} less than T _U ;
Q is the power of the reference heater, expressed in units of BTU / hour; RQ is greater than T _L - T _A.  12. The method according to p. 11, characterized in that the heating duration is equal to expression (I), and the cooling duration is equal to expression (II), when the sum of these expressions is less than a fixed period of 0.5 - 1.3 hours, the heating duration is expression (I) multiplied by p, and the duration of cooling - expression (II) times p, when the sum of these expressions is equal to or greater than the specified fixed period, where p is a coefficient less than 1, determined from the condition that the sum of the heating duration and duration cooling equal to the specified fixed th period. 13. The method according to PP. 5 to 12, characterized in that the sum of the duration of each heating period and the duration of the immediately following cooling period is 5-30 minutes at an ambient temperature of -17.8 to 32.2 ° C (0 - 90 ^o F).  14. The method according to PP. 5 to 13, characterized in that they use a heater, which is a self-regulating heater.  15. The method of maintaining the temperature of the medium above the minimum using an electric heater turned on and off for successive and alternating periods of heating and cooling, the medium being thermally insulated and the heater is placed between the medium and thermal insulation, characterized in that the method includes ( 1) determination of the heating duration for each successive heating period as a function of the ambient temperature near the carrier at one or more separate moments time before the end of the heating period, (2) determining the cooling duration for each successive cooling period as a function of the ambient temperature near the carrier at one or more separate time points before the end of the cooling period, (3) turning on the heater for successive heating periods, the duration of which is determined in step (2), and (4) the heater is turned off for successive cooling periods, the duration of which is determined in step (3), while the sum of the durations of each period n heating and the immediately following cooling period is 2-60 minutes.  16. The method according to p. 15, characterized in that the duration of each heating period and the duration of each cooling period immediately preceding it or immediately following it are functions of the ambient temperature measured at a certain discrete time moment during the immediately preceding heating period or period cooling, and successive discrete time instants are divided into intervals of 5-15 minutes. 17. The method according to p. 15 or 16, characterized in that the heating time is a function of the time required, at an ambient temperature at a separate discrete time point, for heating the reference carrier with a reference heater from the lower limit temperature T _L to the upper limit temperature T _U where the value of T _U -T _L is in the range of 0.5 - 8.3 ^o C (1 - 10 ^o F), and the duration of cooling is a function of the time required, at ambient temperature at a separate discrete time, for cooling the reference nose of Tell T _U - T _L and the reference carrier surround the reference insulation and the reference heater is placed between the reference carrier and the reference insulation. 18. The method according to p. 16, characterized in that the duration of each heating period and the duration of the immediately preceding cooling period or immediately following it are functions of the ambient temperature measured at a certain point in time, and the duration of each heating period in hours is determined by the following expression :
(I) -RC ln [1 - (T _U - T _L ) / (T _A + RQ - T _L )],
and the duration of each cooling period in hours is determined by the following expression:
(II) -RC ln [1 - (T _U - T _L ) / (T _U - T _A )],
where R is the effective thermal resistance of the reference thermal insulation surrounding the reference medium, expressed in units of an hour. ^o F / BTU;
C is the heat capacity of the reference medium, expressed in units of BTU / ^o F;
T _U is the upper temperature limit, expressed in ^o F;
T _L is the lower temperature limit expressed in ° F;
T _A is the ambient temperature at a given point in time, expressed in ° F; T _{A is} less than T _U ;
Q is the power of the reference heater, expressed in units of BTU / hour; RQ is greater than T _L - T _A.  19. The method according to PP. 15 - 18, characterized in that the sum of the duration of each heating period and the duration of the immediately following cooling period is 5-30 minutes at an ambient temperature of -17.8 to 32.2 ° C (0 - 90 ° F).  20. The method according to PP. 15 to 19, characterized in that they use a heater, which is a self-regulating heater.  21. A controller for controlling an electric heater turned on and off for successive and alternating periods of heating and cooling, comprising a sensor for measuring ambient temperature and a switching device for connecting or disconnecting the electric heater from the power source, characterized in that it includes a regulator operatively connected to a sensor and a switching device with the ability to control a switching device for connecting heating a heater to a power source during periods of heating and disconnecting from a power source during cooling periods, and comprising a computing device configured to determine the duration of the heating and cooling periods as a function of ambient temperature, measured by the sensor at one or more previous discrete time instants, separated by periods time not less than 1 min.  22. The controller according to claim 21, characterized in that the controller is configured to determine, as a function of ambient temperature, measured at one or more discrete time instants, the duration of heating, which is a function of the time required to heat a thermally insulated reference carrier from the bottom temperature limit to the upper temperature limit, and the duration of cooling, which is a function of the time required to cool the reference medium from the upper limit temperature eratury to the lower limit temperature, wherein the reference medium surround the reference insulation and the reference heater is placed between the reference carrier and the reference insulation. 23. The controller according to p. 21 or 22, characterized in that the computing device is a microprocessor configured to determine the duration of each heating period in the form of the following expression:
(I) -RC ln [1 - (T _U - T _L / (T _A + RQ - T _L )],
and the duration of each cooling period in the form of the following expression:
(II) -RС ln [1 - (T _U - T _L ) / (T _U - T _A )],
where R is the effective thermal resistance of the reference thermal insulation surrounding the reference carrier, expressed in units of hours. ° F / BTU;
C is the specific heat of the reference medium, expressed in units of BTU / ^o F;
T _U is the upper temperature limit, expressed in ° F;
T _L is the lower temperature limit expressed in ° F;
T _A is the ambient temperature at a given point in time, expressed in ° F; T _{A is} less than T _U ;
Q is the power of the reference heater, expressed in units of BTU / hour; RQ is greater than T _L - T _A.  24. The controller according to paragraphs. 21-23, characterized in that it includes a means of time synchronization for controlling the computing device at discrete points in time, which are divided into time intervals of 5 to 15 minutes 25. A controller for controlling several electric heaters that heat separate zones of a thermally insulated medium, containing at least one input port for receiving information from a sensor that measures the ambient temperature, and several output ports, each of which can transmit signals to the corresponding switching device for turning on or off the power supply of each electric heater in the respective zones, characterized in that it includes a mic a processor adapted to receive ambient temperature information from an input port, having a memory in which thermal characteristics corresponding to the most vulnerable part, which is part of the most rapidly cooled zone, thermal insulation surrounding the specified part, and an electric heater are recorded for each zone heating the indicated part, and is programmed to determine, separately for each zone at discrete consecutive time instants, the durations of consecutive eduyuschihsya heating periods and cooling is needed at the value of ambient temperature is obtained from the input port, for heating the aforementioned part of the zone from a lower limit T _L temperature to a higher temperature and then cooling again to a temperature T _L at the end of the cooling period, the microprocessor is configured also with the ability to transmit signals to the output port associated with the corresponding zone for turning on and off the aforementioned heater for sequential and alternating periods of heating Islands and cooling. 26. The controller according to claim 25, characterized in that the microprocessor is programmed to determine the heating and cooling periods, which are functions for the time periods necessary for heating the aforementioned most vulnerable part of the zone from the lower limit temperature T _L to the upper limit temperature T _U and subsequent cooling again to T _L.